Inactivation as a New Regulatory Mechanism for Neuronal Kv7 Channels

Biophysical Journal

Volume 92

April 2007

2747–2756

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Inactivation as a New Regulatory Mechanism for Neuronal Kv7 Channels Henrik Sindal Jensen,*z Morten Grunnet,*y and Søren-Peter Olesen*y *The Danish National Research Foundation Centre for Cardiac Arrhythmia, Department of Medical Physiology, The Panum Institute, University of Copenhagen, DK-2200 Copenhagen N, Denmark; yNeuroSearch A/S, Ballerup, Denmark; and zH. Lundbeck A/S, Copenhagen, Denmark

ABSTRACT Voltage-gated K1 channels of the Kv7 (KCNQ) family have important physiological functions in both excitable and nonexcitable tissue. The family encompasses five genes encoding the channel subunits Kv7.1–5. Kv7.1 is found in epithelial and cardiac tissue. Kv7.2–5 channels are predominantly neuronal channels and are important for controlling excitability. Kv7.1 channels have been considered the only Kv7 channels to undergo inactivation upon depolarization. However, here we demonstrate that inactivation is also an intrinsic property of Kv7.4 and Kv7.5 channels, which inactivate to a larger extent than Kv7.1 channels at all potentials. We demonstrate that at least 30% of these channels are inactivated at physiologically relevant potentials. The onset of inactivation is voltage dependent and occurs on the order of seconds. Both time- and voltage-dependent recovery from inactivation was investigated for Kv7.4 channels. A time constant of 1.47 6 0.21 s and a voltage constant of 54.9 6 3.4 mV were determined. It was further demonstrated that heteromeric Kv7.3/Kv7.4 channels had inactivation properties different from homomeric Kv7.4 channels. Finally, the Kv7 channel activator BMS-204352 was in contrast to retigabine found to abolish inactivation of Kv7.4. In conclusion, this work demonstrates that inactivation is a key regulatory mechanism of Kv7.4 and Kv7.5 channels.

INTRODUCTION The Kv7 family of ion channels has received much attention since they have been identified as the molecular correlates of several important human K1 conductances. The Kv7 family is unique in the sense that mutations in four of the five genes have been linked to human hereditary diseases (1,2). Within the Kv7 family the most thorough characterization has been performed on the Kv7.1 channel (for a recent review see Jespersen et al. (3)). It was cloned in 1996 from patients suffering from the proarrhythmic condition long QT syndrome (4) and later demonstrated to associate with the b-subunits KCNE1 to constitute the cardiac IKs current (5,6). The neuronal M-current was first described in 1980 as slowly activating, noninactivating K1 current, which could be inhibited through activation of muscarinic receptors (7). The molecular component behind the M-current was later identified as Kv7.2 and Kv7.3, and it has been demonstrated how mutations in these genes are linked to a neonatal form of epilepsy (8–12). Kv7.4 was cloned in 1999 and mutations in this gene have been associated with deafness (13–15). Kv7.5, like Kv7.2–4, is primarily neuronal, although no disease has yet been associated to mutations in this gene (16–18). Due to the tight coupling of Kv7 channels to dysfunction and disease, great effort has been invested to understand the regulation of these channels. Kv7.1 channels are modulated by a number of factors including protein kinase A (PKA) and protein kinase C (PKC), cell volume changes, external acid-

Submitted November 16, 2006, and accepted for publication January 4, 2007. Address reprint requests to Henrik Sindal Jensen, Dept. of Molecular and Cellular Pharmacology, H. Lundbeck A/S, Ottiliavej 9, DK-2500 Copenhagen, Denmark. Tel.: 45-36-43-26-23; Fax: 45-36-43-82-71; E-mail: [email protected]. Ó 2007 by the Biophysical Society 0006-3495/07/04/2747/10 $2.00

ification, and phosphatidyl inositol phosphate (PIP2) (19–24). Additionally, Kv7.1 channel activity can be regulated by interaction with all members of the KCNE family of b-subunits (5,6,25–28). As the molecular correlates of the M-current, Kv7.2 and Kv7.3 can be inhibited via muscarinic M1 receptor activation, although inhibition of the M-current can also be achieved through activation of other G-protein coupled receptors (29–31). PIP2 has been demonstrated to be the link between muscarinic receptors and the M-current (32–35), and it is necessary for maintaining channel activity. Kv7.4 channels are regulated by factors such as PKA, PKC, intracellular Ca21, changes in cell volume, PIP2, and phosphorylation by glucocorticoid-inducible kinases (19,36,37). Finally, changes in cell volume, extracellular Zn21, acidification, and muscarinic receptor activation modulate Kv7.5 (16,17). In addition to the described regulations, Kv7 channel activation is voltage dependent. A common feature is an initial opening at potentials around 60 mV and a slow time constant for both activation and deactivation compared to other voltage-gated K1 channels. One biophysical parameter that differentiates the Kv7 channel subtypes is inactivation. Inactivation has been reported for Kv7.1 channels and has been demonstrated to be time and voltage dependent (5,6). Coassembly with either KCNE1 or KCNE4 b-subunits can eliminate Kv7.1 channel inactivation (38–40). In contrast, it is generally believed that Kv7.2-5 channels—along with the M-current—do not inactivate (7,11, 13,17,18,39). However, a recent report shows that the activity of Kv7.4 channels can be augmented by hyperpolarizing prepulses, indicating that they may undergo inactivation (37). We have devoted this study to a thorough investigation of the

doi: 10.1529/biophysj.106.101287

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possible inactivation properties of all the Kv7 channels with emphasis on Kv7.4 channels.

MATERIALS AND METHODS Molecular biology cRNA was synthesized by standard T7 in vitro run-off transcription of human Kv7.1, Kv7.2, Kv7.3, and Kv7.4 and murine Kv7.5. A total of 50 nl of ;0.5 mg/ml cRNA was injected into stage V–VI oocytes isolated from Xenopus laevis according to national guidelines. Oocytes were kept at 19°C in Kulori solution (in mM: 90 NaCl, 1 KCl, 1 MgCl2, 1 CaCl2, 5 HEPES, pH 7.4) and currents could be detected after 2–3 days.

Electrophysiology Conventional two-electrode voltage-clamp recordings were conducted at room temperature in Kulori solution using a Dagan CA-1D amplifier (Minneapolis, MN) and Pulse software (HEKA, Lambrecht/Pfalz, Germany). The borosilicate electrodes were filled with 1 M KCl and had a tip resistance of 0.5–2 MV. All drugs were dissolved in dimethylsulfoxide (DMSO) and diluted so the final DMSO concentration was ,0.3%. At this concentration no vehicle effects were observed. Retigabine, BMS-204352, and XE-991 were synthesized at NeuroSearch A/S.

Calculations Data were obtained from more than one batch of oocytes, and analyses were performed in SigmaPlot. Data analyses were done with the MarquardtLevenberg algorithm, and decaying currents were best fitted to a threeparameter single exponential function: I(x) ¼ AN 1 A 3 exp(x/t). Rising currents were best fitted to a three-parameter single exponential function: I(x) ¼ A0 1 A 3 (1  exp(x/t). For both equations I(x) is the current at time or voltage x, A is the amplitudes of the exponential, and t is the time or voltage constant. For functions describing an exponential decline AN is the horizontal asymptotic value at time N, and for those describing an

Jensen et al. exponential rise A0 is the current amplitude at time 0. The percentage of control are calculated as the Ix/ICTRL 3 100%, where Ix is the normalized current amplitude after retigabine, XE-991, or BMS-204352 application and ICTRL is the corresponding current amplitude recorded in Kulori solution. Normalization is done to the current amplitude recorded at Vact ¼ 140 mV after a Vpre of 120 mV. The linear curve fits on the percentage of control data for the pharmacological experiments are fitted to p(x) ¼ ax 1 b, where p(x) is the percentage of control at potential x, a is the slope, and b the crossover point of x ¼ 0. Values are given as mean 6 SE where n indicates the number of observations, and the mean is calculated as the mean of the particular parameter from several individual fits.

RESULTS Inactivation properties of homomeric Kv7.1-5 channels The extent of inactivation of homomeric Kv7.1, 2, 4, and 5 channels was investigated by two-electrode voltage clamp experiments in Xenopus oocytes. After injection of the respective cRNAs, typical Kv7 currents could be activated by standard voltage-step protocols consisting of a 3-s prepulse at 80 mV (Vpre), a 2-s activation pulse at gradually more positive potentials from 100 to 160 mV in 20-mV increments to activate the channels (Vact), and ended by a 1-s step to 30 mV to facilitate recording of the tail current (Fig. 1, A–D). Water-injected control oocytes did not give rise to interfering currents. From such experiments, the inactivation of the Kv7 channels is normally not visible, although indication of an inactivation process can be seen from a small hook on the tail current indicative of a release from inactivation (e.g., Fig. 1, A and D). To study this phenomenon in more detail, we designed the inactivation protocol shown in Fig. 2 with an initial

FIGURE 1 Two-electrode voltage-clamp experiments on Kv7.1, 2, 4, and 5 homomeric channels in Xenopus oocytes (A–D). The channels were activated by voltage steps from 80 mV to potentials ranging from 100 to 160 mV in 20-mV increments (2-s duration), and tail currents were measured at 30 mV. Indications of an inactivation process of Kv7.1 and Kv7.5 can be seen by the small hook on the tail current caused by release from inactivation during the initial phase of the 1-s pulse to 30 mV as well as the marked difference in activation/deactivation kinetics.

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FIGURE 2 Magnitude of inactivation. (A–D) The inactivation properties of homomeric Kv7 channel complexes were investigated by voltage-clamp experiments in Xenopus oocytes. After a 20-s-long prepulse at potentials ranging from 120 mV to 160 mV (Vpre), the maximal current amplitudes were measured during a 5-s pulse at 140 mV (Vact) for each channel subtype: A. Kv7.1, B. Kv7.2, C. Kv7.4, and D. Kv7.5 (inset shows the voltage protocol). (E) The degree of inactivation of each Kv7 channel complex is revealed by plotting the current amplitude normalized to the level measured after a Vpre of 120 mV as a function of the preceding Vact potential. Maximal inactivation of ;80% is observed for Kv7.5 at 160 mV.

20-s-duration Vpre to clamp the cell membrane at holding potentials of 120 mV to 160 mV in 20-mV increments. This step was followed by a Vact step to 140 mV. During the 5-s test pulse at 140 mV the noninactivated channels do activate fully, but since they also to some degree inactivate during the test pulse, we use the peak current as a measure of available channels. Due to the channels inactivating during the upstroke of the test current, the protocol may tend to overestimate the degree of inactivation. Plotting the maximal current amplitudes measured during the Vact step to 140 mV as a function of the preceding Vpre holding potential clearly revealed the steady-state inactivation of homomeric Kv7.1, Kv7.4, and Kv7.5 (Fig. 2, A–D). At physiologically relevant potentials, inactivation was most pronounced for Kv7.4 and Kv7.5, which displayed an inactivation of ;30% at Vpre ¼ 50 mV when compared to Vpre ¼ 120 mV (Fig. 2 E). These experiments demonstrate that in a typical resting neuron (Vm ; 70 mV), significant Kv7 channel inactiva-

tion occurs. For the following in-depth investigations, we focused on Kv7.4. Onset of inactivation The onset of inactivation was studied by a three-step protocol consisting of a 10- or 20-s prepulse clamping the cell membrane at 120 mV to recover from inactivation, followed by a step to 0 mV of variable duration (0–28 s in 2-s increments), allowing different degrees of channel inactivation, and finally a 5-s step to 140 mV (Fig. 3 A). The time-dependent onset of inactivation is shown by plotting the maximal current amplitude recorded at the Vact step to 140 mV as a function of the time spent at 0 mV (Fig. 3 B). The results could best be fitted to a three-parameter one-exponential function: I(x) ¼ AN 1 A 3 exp(x/t), which gave a mean decay time constant, t, of 9.55 6 1.14 s, a noninactivation component, AN, of 31% 6 2.8%, and a relative amplitude of Biophysical Journal 92(8) 2747–2756

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the inactivating current, A, of 72% 6 3.5%, n ¼ 7. To investigate if the 10-s prepulse at 120 mV was long enough to facilitate full recovery from inactivation, we repeated the experiment with a Vpre at 120 mV of 20 s. This resulted in a significantly faster inactivation (t of 5.06 6 1.10 s, n ¼ 3; P , 0.05, Student’s t-test) and a significantly lower maximal inactivation and amplitude of the exponential (AN ¼ 48% 6 4.3%, P , 0.01 and A ¼ 51% 6 3.9%, P , 0.05), indicating that some inactivation must remain even during a 10-s prepulse at 120 mV (Fig. 3 B).

Time-dependent recovery from inactivation The time-dependent recovery from inactivation of Kv7.4 was studied by a two-step protocol composed of a 20-s-long prepulse at 120 mV followed by a 5-s activation pulse to 140 mV (V1act). During this first depolarizing pulse the channels inactivate. To quantify the time needed to recover from inactivation, this pulse was followed by a hyperpolarizing step to 120 mV ranging from 250 ms to 3750 ms in 250-ms increments. The recovery from inactivation is reflected in the current amplitude elicited by a second pulse to 140 mV (V2act)

Jensen et al.

(Fig. 4 A). A clear time-dependent recovery from inactivation was shown by plotting the current amplitude of V2act in percentage of the preceding V1act maximal current amplitude as a function of the time spent at 120 mV. This could best be fitted to a rising three-parameter one-exponential function with a time constant of 1.47 6 0.21 s, an A0 of 69.8% 6 2.6%, and an A of 24.8% 6 3.0%, n ¼ 7 (Fig. 4 B).

Voltage-dependent recovery from inactivation Not only increasing time but also increasing hyperpolarizing potentials would be expected to release the inactivation of Kv7.4. We employed a protocol similar to that shown in Fig. 4, but the time between V1act and V2act fixed at 3 s. The variable parameter in this experiment was the holding potential of the intermediate hyperpolarizing step that releases the inactivation, which was clamped at potential ranging from 30 to 120 mV (Fig. 5 A). Similar to the time dependence experiments, we plotted the maximal current amplitude of V2act in percentage of the V1act maximal current amplitude but now as a function of the holding potential of the intermediate hyperpolarizing step (Fig. 5 B). Fitting these

FIGURE 3 Time dependence of inactivation. (A) The onset of inactivation of Kv7.4 at 0 mV was studied by a two-step protocol designed to allow the channels to inactivate increasingly. The inset in B shows the voltage protocol employed, which clamped the cell membrane at 120 mV for 20 s to allow for recovery from inactivation (Vpre), followed by a step to 0 mV of 0–28-s duration in 2-s increments. The second step was a depolarizing step to 140 mV for 5 s during which the maximal current amplitude was measured. This experiment was also performed with a 10-s-long Vpre (current traces not shown). (B) Plotting the maximal current amplitude normalized to the amplitude at V0 mV, 0 s as a function of the time spent at 0 mV revealed a single-exponential correlation of the onset of inactivation for both protocols. Fitting the data from the two experiments to I(x) ¼ AN 1 A 3 exp(x/t) gave significantly different time constants: t10 s prepulse ¼ 9.55 6 1.14 s (n ¼ 7) and t20 s prepulse ¼ 5.06 6 1.10 s (n ¼ 3); P , 0.05, t-test. The curves are generated from the fitted parameters.

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FIGURE 4 Time-dependent recovery from inactivation of Kv7.4. (A) The time course of recovery from inactivation was studied by a two-step protocol in which two activating pulses follow a 20-s-long hyperpolarizing pulse at 120 mV. Each 140-mV pulse (V1act and V2act) is of 5-s duration, and the variable parameter is the length of the separating 120 mV hyperpolarizing pulse. The duration of the hyperpolarizing pulse ranges from 250 ms to 3750 ms in 250-ms increments (inset shows the voltage protocol). (B) The maximal current amplitude at V2act is depicted in percentage of the maximal current amplitude at V1act subtracting the A0 (the calculated current amplitude in percentage at time 0) as a function of the release time at 120 mV (i.e., I[V2act]/I[V1act] 3 100%  A0), and this revealed a single-exponential relationship between the release time and the degree of recovery from inactivation. Fitting the data to I(x) ¼ A0 1 A 3 (1  exp(x/t)) gave a time constant t ¼ 1.47 6 0.21 s (n ¼ 7). The curve is generated from the fitted parameters.

data to a three-parameter one-exponential decaying function resulted in a voltage constant of 54.9 6 3.4 mV, AN ¼ 39.7% 6 3.7%, and A ¼ 6.0% 6 0.88%, n ¼ 10 (Fig. 5 B). Kv7.3 modulates the Kv7.4 inactivation As Kv7.3 and Kv7.4 can form functionally distinct heteromers (13), we wanted to investigate the inactivation properties of coexpressed Kv7.3 and Kv7.4, and we did this by a protocol comparable to the one shown in Fig. 2 (Fig. 6 A). A significant difference in the inactivation properties of homomeric Kv7.4 versus heteromeric Kv7.314 channels was evident in the range 40 mV–160 mV when plotting the maximal current amplitude of the Vact step as a function of the Vpre potential (Fig. 6 B). In contrast to homomeric Kv7.4 channels, which display a flat S-shaped course in the inactivation behavior with no local maximum, heteromeric Kv7.314 channels display less inactivation between Vpre of 20 mV and 140 mV where the maximal amplitude reaches 89.0% 6 3.5%, n ¼ 10 at Vpre ¼ 120 mV relative to Vpre ¼ 120 mV (homomeric Kv7.4 amplitude at Vpre ¼ 20 mV is 65.7% 6 2.8%, n ¼ 27 relative to Vpre ¼ 120). Pharmacological modulation of inactivation A handful of compounds has been used to address the function of Kv7 channels (e.g., retigabine, XE-991, and BMS-204352). The positive modulator retigabine presently

undergoing clinical phase III studies has especially been the subject of intense study. It has been shown that retigabine enhances the open probability, shifts the activation curve leftward, and increases the macroscopic current of Kv7 channels (16,41–44). However, none of these studies has investigated the effect on the inactivation of Kv7.4. To address this we employed the standard inactivation voltage protocol, as used in Figs. 2 and 6, in the absence and presence of 10 mM retigabine (Fig. 7, A and B). The two curves describing the measured currents at each potential normalized to the control current at 120 mV and plotted as a function of Vpre were parallel over the range of Vpre tested (120 mV–180 mV) (Fig. 7 E). When plotting the retigabine-induced current relative to the control current at each potential the modulation of inactivation by retigabine was also minor (the potentiation ranged from 170% 6 15% at a Vpre of 120 mV to 269% 6 50% at a Vpre of 180 mV, n ¼ 7). We quantified this as the slope of the best linear fit to the percentage of control data, which was calculated as aRTG ¼ 0.33% 6 0.21%/mV, n ¼ 7 (Fig. 7, E–G). In a similar manner we tested if the inhibitory effect of XE-991 was related to a changed inactivation. Hence, 100 mM XE-991 was applied as described above, and the rate of inactivation of Kv7.4 was compared before and after drug application (Fig. 7, A and D). As with retigabine, the maximal current amplitude relative to control conditions over the range of Vpre tested was close to parallel and in the range of 40%–45% (45% 6 4.3% at Vpre ¼ 120 mV to Biophysical Journal 92(8) 2747–2756

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FIGURE 5 Voltage-dependent recovery from inactivation of Kv7.4. (A) The kinetics of recovery from inactivation was studied by a two-step protocol similar to the one used in the time-dependent recovery experiments, but with the duration of the release pulse fixed at 3 s. The variable in this experiment was the voltage employed to clamp the membrane during the release pulse, which ranged from 120 mV to 30 mV in 10-mV increments (inset shows the protocol). (B) The maximal current amplitude recorded at V2act in percentage of the corresponding amplitude of V1act plotted as a function of the holding potential of the release pulse could best be fitted to a single-exponential function: I(x) ¼ AN 1 A 3 exp(x/t), resulting in a voltage-constant t ¼ 54.9 6 3.4 mV (n ¼ 10).

45% 6 8.6% at Vpre ¼ 180 mV, n ¼ 5). The slope of the best linear fit was calculated to aXE-991 ¼ 0.016% 6 0.017%/ mV, n ¼ 5 (Fig. 7, E–G). BMS-204352 was originally developed for the treatment of stroke, and the mechanism was thought to be by opening BK channels (45). However, it has also been shown to be a potent activator of Kv7 channels (41,46,47). A detailed characterization of the mode of action on the Kv7 channels has not yet been described, so we investigated the effect of BMS-204352 on the inactivation properties of Kv7.4. A total of 10 mM BMS-204352 potentiated the current to 690% 6 106%, n ¼ 5 of control measured at the end of a depolarizing step during the following repeated voltage protocol: 4 s at 80 mV, 2 s at 140 mV, and 1 s at 30 mV (not shown). In contrast to retigabine and XE-991, a clear effect on inactivation was observed with BMS-204352 (Fig. 7, A and C). The maximal Vact current amplitude increased over the range of Vpre tested from 578% 6 15% of control at Vpre ¼ 120 mV to 1745% 6 422% at Vpre ¼ 180 mV, n ¼ 3. The slope of the best linear fit of the percentage of control data reflects abolishment of Kv7.4 inactivation by BMS-204352, as it was calculated to aBMS ¼ 5.24% 6 1.51%/mV, n ¼ 3 (Fig. 7, E–G). DISCUSSION The nonneuronal Kv7.1 potassium channel has been described to inactivate (38,39,48), whereas the general notion Biophysical Journal 92(8) 2747–2756

has been that the other Kv7 family members do not inactivate. Contrary to this general view on the biophysical properties of the neuronal Kv7 channels, we here show that Kv7.4 and Kv7.5 channels indeed do inactivate. We have performed detailed studies on Kv7.4 showing that the macroscopic inactivation is voltage dependent and is augmented as a function of increased holding potentials, reaching a maximum .60% at 180 mV. Kv7.4, as well as Kv7.5 channels, was found to inactivate to a larger extent than Kv7.1. The kinetics of Kv7.4 channel inactivation is slow, with time constants of 5–10 s depending on the duration of the preceding hyperpolarizing pulse (t 10 s prepulse ¼ 9.55 6 1.14 s and t 20 s prepulse ¼ 5.06 6 1.10 s). Recovery from inactivation of Kv7.4 is both time and voltage dependent. When inactivation was released by hyperpolarizing pulses at 120 mV at increasing time intervals, the recovery from inactivation was clearly time dependent with a time constant of 1.47 6 0.21 s. The inactivation kinetics of Kv7.4 is apparently much slower than that of Kv7.1, as Tristani-Firouzi and Sanguinetti found that Kv7.1 inactivates monoexponentially at 120 mV with a time constant of 130 ms after an initial delay of ;75 ms (38). The time constants for recovery from inactivation of Kv7.1 was likewise much faster, ranging from 30–40 ms and showing very little voltage dependence at voltages ranging from 90 to 30 mV (38). However, since the kinetics of inactivation and recovery from inactivation in their study was determined from the hooked tail current, they may only reflect the early phase of both

Inactivation of Kv7 Channels

FIGURE 6 Kv7.314 heteromers inactivate differently from Kv7.4 homomers. (A) Cells expressing heteromeric Kv7.314 channels were investigated for the inactivation behavior of the respective channels with the same voltage protocol as in Fig. 2 (expanded to include a prepulse step to 180 mV). (B) The figure shows the normalized maximal current recorded at a 5-s-long depolarizing pulse to 140 mV preceded by a 20-s-long prepulse (Vpre) ranging from 120 mV to 180 mV in 20-mV increments for both Kv7.4 and Kv7.3 1 4. Current amplitudes are plotted as a function of the holding potential during the 20-s-long prepulse, and the two channel complexes are significantly different in this respect after a prepulse ranging from 40 mV to 160 mV. Asterisks indicate the level of significance (*, P , 0.05; **, P , 0.005, t-test, n ¼ 10 and 27, Kv7.3 1 4 and Kv7.4, respectively).

phenomena. The degree of Kv7.1 inactivation in both studies was found to be ;35% at 140 mV with a similar voltage dependence despite the different protocols used to reflect the inactivation. It has been demonstrated that Kv7.3 and Kv7.4 can form functional heteromers (13), so we investigated if such complexes had an inactivation profile different from Kv7.4 homomers. The quantity of inactivated heteromers was significantly decreased at potentials from 40 mV to 1 60 mV. This indicates that more active Kv7.3 1 Kv7.4 channel complexes will be present at these potentials relative to homomeric Kv7.4 channels. In a final investigation we addressed if different Kv7 channel modulators had any impact on the inactivation prop-

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erties of the channels. It was demonstrated that the Kv7.4 channel activator retigabine and the inhibitor XE-991 did not mediate their effects through changed inactivation. In contrast, BMS-204352 abolished the inactivation of Kv7.4 channels. These data demonstrate that the Kv7 openers retigabine and BMS-204352 have distinct modes of action. It is known from Kv7.1 inactivation that this can be abolished by coexpression with KCNE1 (minK), which is in agreement with the notion that the endogenous IKs current does not inactivate (38). It has been suggested that this modification of the channel kinetics is accomplished by the C-terminus of KCNE1 protruding into the Kv7.1 complex and binding to the pore loop (49). The modest effect of Kv7.3 and retigabine as opposed to the strong effect of BMS204352 on Kv7.4 inactivation may likewise be caused by the physical interaction resulting in an allosteric modulation of the channel complex. However, we do not know the specific binding sites of these molecules to the Kv7.4 complex. It is likely that BMS-204352 binds to a site other than retigabine, since they are structurally quite different molecules. Further, the two compounds modify the Kv7 channel subtypes differentially since BMS-203352 blocks Kv7.1 whereas retigabine shows no effect on this channel (44,50). Likewise, the drugs show differential effects on the neuronal Kv7 channels (51). One of the ways a drug can activate an ion channel is by removing its inactivation, as is the case for BMS-204352. The effects of BMS-204352 is, however, significantly larger than what can be accounted for by reduced inactivation alone (Fig. 7). The compound also activates the Kv7.4 channel by shifting the voltage-dependent activation curve toward negative values (50) as well as by activating a voltage-independent Kv7.4 current (41). Since the open probability of Kv7.4 channels at positive membrane potentials is only ;0.18 (52), there is room for an increased opening of the channel in the presence of compound, which must also occur for the current to increase by more than fivefold at the noninactivation potential of 120 mV. In this study Kv7.4 and Kv7.5 are found to inactivate to the largest degree, whereas Kv7.2 does not inactivate. Kv7.4 and Kv7.5 exhibit a number of similar characteristics in contrast to Kv7.2: Kv7.4 has a greater amino acid sequence homology with Kv7.5 than with Kv7.2; pharmacologically BMS-204352 activates Kv7.4 and Kv7.5, whereas it does not modify Kv7.2/3 (50); biophysically the unitary currents of Kv7.4 and Kv7.5 are 2.1 and 2.2 pS, whereas that of Kv7.2 is 6.2 pS (52,53); the maximal open probability of Kv7.4 and Kv7.5 are 0.18 and 0.17, respectively, whereas it is 0.07 for Kv7.2. This does not in itself explain why Kv7.4 and Kv7.5 inactivate and Kv7.2 does not, and to address this question it is important to study the residues in the Kv7 channels involved in the inactivation process of which we currently have no clear indication. This study shows that Kv7.4 channel inactivation is different from classical N- and C-type inactivation found in Biophysical Journal 92(8) 2747–2756

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FIGURE 7 Pharmacological modulation of Kv7.4 inactivation. (A–D) Two-electrode voltage-clamp experiments on three different oocytes under control conditions (A) and after application of 10 mM retigabine (RTG; B), 10 mM BMS-204352 (C), and 100 mM XE-991 (D). The voltage protocol consist of a 20-s-long prepulse (Vpre) ranging from 120 mV to 180 mV in 20-mV increments, followed by a depolarizing step to 140 mV (Vact) and ended by a 1-s step to 30 mV. The scale bars are for control and RTG traces 3 mA and 5 s, for the BMS experiment 6 mA and 5 s, and for XE-991 1 mA and 5 s. (E) Plot showing the normalized current levels before and after application of RTG, BMS, and XE-991, respectively. (F) Graphs illustrate the best linear fit of the measured current expressed as percentage of control data. Best-fit slope values are (in percentage per mV) aRTG ¼ 0.33 6 0.21 (n ¼ 7), aXE-991 ¼ 0.016 6 0.017 (n ¼ 5), and aBMS ¼ 5.24 6 1.51 (n ¼ 3). (G) Histogram illustrating the differences between the slope values determined for RTG, BMS, and XE-991.

voltage-gated Na1 channels and voltage-gated K1 channels of the Shaker type (38,48,54–57). Features that distinguish Kv7.4 inactivation from N- and C-type inactivation are slow onset and voltage dependency. This is also true for Kv7.1 inactivation (38), suggesting that the inactivation mechanism for these two Kv7 channel subtypes are similar. The inactivation property may have important bearings for the pathophysiology and pharmacology of the neuronal Kv7 channels. Within the family of Kv7 channels, inactivation at physiologically relevant potentials was most prominent for Kv7.4 and Kv7.5 channels. Of the five Kv7 channel subunits, Kv7.4 displays the most restricted expression pattern, being present in the inner ear and the auditory pathways of the brain but also in certain dopaminergic neurones (58,59). Hence, Kv7.4 channels could represent a particularly relevant target for treatment with drugs specifically activating the Kv7.4 channel as efficacy, and side effect profiles of such a compound could prove superior to panreactive compounds affecting all neuronal members of the Kv7 family. In conclusion we have described inactivation as a new regulatory mechanism for Kv7.4 and Kv7.5 channels. At physiologically relevant resting potentials, the current is reduced by more than 30% due to steady-state inactivation. These results add to a more profound understanding of the biophysical nature of the Kv7 channel family and their physiological impact. Pharmacological channel modulators influence the inactivation properties differentially, so this newly discovered regulatory mechanism is of further imBiophysical Journal 92(8) 2747–2756

portance when developing drugs targeted for these channels. Physiological signaling molecules may also influence the steady-state inactivation of Kv7 channels, and if this proves to be the case it will be an efficient way of modulating neuronal excitability. Prof. Thomas Jentsch is acknowledged for kindly supplying human Kv7.2, 3, and 4 cDNA and Prof. Michel Lazdunski for supplying Kv7.1 cDNA. This work was supported by the Danish National Research Foundation and the Danish Medical Research Council (to S.P.O.).

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